Is zeaxanthin needed for desiccation tolerance? Sustained forms of thermal dissipation in tolerant versus sensitive bryophytes

Desiccation tolerant (DT) plants engage and disengage sustained forms of energy dissipation in response to desiccation and rehydration. This project sought to characterize the role of zeaxanthin and thylakoid protein phosphorylation status in sustained energy dissipation during desiccation in bryophytes with varying DT. Tolerant ( Polytrichum piliferum , Dicranum species, Calliergon stramineum ) and sensitive ( Grimmia species, Schistidium rivulare , Sphagnum species) moss were desiccated in darkness or natural light conditions for up to three weeks. Desiccation caused pronounced reductions in F v / F m in all cases which was enhanced by light exposure during desiccation. Desiccation in darkness resulted in no accumulation of Z in any species, however, in natural light conditions there was significant accumulation of Z in tolerant but not sensitive species. Desiccation in natural light, relative to darkness, resulted in more pronounced reductions in F o in tolerant but not sensitive species. Recovery of F v / F m upon rehydration occurred in two phases, a rapid phase (minutes) and a slower phase (hours). Increased time of desiccation, and light exposure, resulted in a reduction in the rapid phase. Desiccation in light conditions resulted in some accumulation of the phosphorylated form of the major light harvesting trimer (LHCII). Data are consistent with two mechanisms of sustained quenching, neither of which requires Z . However, when desiccation occurs in natural light conditions, accumulation of Z likely contributes to one or both of the sustained forms of dissipation. Increases in LHCII phosphorylation during desiccation are consistent with increased connectivity between the photosystems. The absence of Z formation in sensitive species may contribute to their lack of desiccation tolerance.